CS259922B1 - Connection of control station for calibration of measuring transducers - Google Patents

Abstract

The solution concerns the field of measurement of alternating quantities of technical frequencies. The circuit solves the technical problem of generating three-phase current and three-phase voltage with the possibility of setting any phase shift by a portable device with low weight. The essence of the solution lies in generating three-phase output current and three-phase output voltage from a single source of a two-state signal, which will allow, using galvanic isolation circuits of the two-state signal, to simply bridge the necessary potential difference between the three-phase current amplifier and the three-phase voltage amplifier, without significantly affecting the phase shift between the output signals by the galvanic isolation circuits.

Description

The invention relates to the connection of a control station for calibrating measuring transducers generating a three-phase current and a three-phase voltage shifted by a set phase angle independent of the load pattern.

The hitherto known connections are based either on large and very massive electromechanical elements requiring a three-phase supply voltage, in which the output signal frequency is determined by the supply voltage frequency, or are considerably more complex and unsuitable for their weight and low shock resistance.

SUMMARY OF THE INVENTION The multivibrator output is connected to an input of a frequency meter, which is connected to an input of a three-phase current shaping circuit, the first output of which is connected to a first input of a three-phase current amplifier. the third output of the three-phase current shaping circuit is connected to the third input of the three-phase current amplifier, the first active output of which is connected to one galvanically free load of the phase X current circuit, the other end of which is connected to the first comparative output of the three-phase current amplifier connected to the first current input of the overload circuit, the second active output of the three-phase current amplifier is connected to one end of the galvanically free load of the phase Y current circuit, onec is connected to the second comparator output of the three-phase current amplifier, which is connected to the second current input of the overload circuit, the third active output of the three-phase current amplifier is connected to one end of the galvanically free load of the phase Z current circuit. a three-phase current amplifier connected to the third current input of the overload circuit, the multivibrator output also being connected to the input of the first galvanic isolation circuit whose output is connected to the input of the three-phase voltage shaping circuit, the first output of which is connected to the first input of the three-phase voltage amplifier; wherein the second output of the three-phase voltage shaping circuit is connected to the second input of the three-phase voltage amplifier, the third output of the three-phase voltage shaping circuit is connected to the t a third input of a three-phase voltage amplifier whose first output is connected to a common output of a three-phase voltage amplifier via a common zero-load voltage circuit of a phase X whose second output is also connected to a common output of a three-phase voltage amplifier the third output is also connected to a common output of the three-phase voltage amplifier via a common zero-load voltage circuit, the first overcurrent output of which is connected to the first overload voltage input, the second overcurrent output of the three-phase voltage amplifier is connected to the second overload circuit wherein the third overcurrent output of the three-phase voltage amplifier is connected to the third voltage input of the overload circuit, the output of which is connected to the blocking input of the three-phase current an amplifier which is connected to an input of a third galvanic isolation circuit, the output of which is connected to a blocking input of a three-phase voltage amplifier, the control output of the three-phase current shaping circuit being connected to the input of a phase shift circuit the output is connected to the control input of a three-phase voltage shaping circuit.

The circuitry according to the invention by electronically generating a three-phase current and a three-phase voltage with the possibility of adjusting phase, frequency and amplitude is independent of the type of supply voltage.

It allows to check the accuracy of all AC transducers, frequency relays in the line frequency range and phase sensitive instruments in the range of 0 to 360 °. Due to its low weight, it is suitable for transport to work stations with measuring transducers without the need to dismantle them, and is equipped with electronic overload protection at its outputs.

The attached drawing shows the wiring of a control station for calibration of measuring transducers.

The interconnection of a particular embodiment according to the invention is formed by connecting the output 101 of the multivibrator 1 to the input 201 of the meter 2 / which is connected to the input 301 of the three-phase current shaping circuit 2. the second output 303 of the three-phase current shaping circuit 3 is connected to the second input 402 of the three-phase current amplifier 4, and the third output 304 of the three-phase current shaping circuit 2 is to the third input 403 of the three-phase current amplifier 2. a phase X current circuit load 12, the other end of which is connected to a first comparative output 405 of a three-phase current amplifier 2 which is connected to a first current input 1001 of the overload circuit 10, the second active output 406 of a three-phase current the amplifier 2 ³ and connected to one end electrically loose load 13 circuit of Y, the other end is connected to the second comparator output 407 three-phase current amplifier £ which is connected to the second current input 1002 circuit 10 overloaded, the third active output 408 of the three-phase current amplifier 4 is connected to one end of the galvanically free load 14 of the phase Z current circuit, the other end of which is connected to the third comparing output 409 of the three-phase current amplifier 4 which is connected to the third current input

The output 101 of the multivibrator 2 is also connected to the input 501 of the first galvanic isolation circuit 2, whose output 502 is connected to the input 801 of the three-phase voltage forming circuit 2, whose first output 802 is connected to the first input 901 of the three-phase voltage amplifier. wherein the second output 803 of the three-phase voltage forming circuit 2 is connected to the second input 902 of the three-phase voltage amplifier 9, the third output 804 of the three-phase voltage forming circuit 2 is connected to the third input 903 of the three-phase voltage amplifier. the voltage of the X-phase voltage circuit is connected to the common output 910 of the three-phase voltage amplifier 2, whose second output 907 is also connected to the common output 910 of the three-phase voltage amplifier 9, despite the load the third output 909 is also connected to the common output 910 of the three-phase voltage amplifier 9 via a common zero-load voltage circuit 17 of the phase Z whose first overcurrent output 904 is connected to the first voltage input

004 of the overload circuit 10, wherein the second overcurrent output 906 of the three-phase voltage amplifier 9 is connected to the second voltage input 1 005 of the overload circuit 10, wherein the third overcurrent output 908 of the three-phase voltage amplifier 9 is connected to a third voltage input 007 is connected to the blocking input 4 010 of the three-phase current amplifier 2, which is connected to the input 1 101 of the third galvanic isolation circuit 11, whose output 1 102 is connected to the blocking input 9 011 of the three-phase voltage amplifier. is connected to the input 601 of the phase shift circuit 2, whose output 602 is connected to the second circuit input 701 of galvanic isolation, whose output 702 is connected to the control input 805 of the three-phase voltage forming circuit 8.

The two-state output signal generated in the multivibrator 2, whose frequency is measured in the frequency meter 2, enters the three-phase current shaping circuit 2, which generates three alternating signals offset by 120 ° relative to each other via its sinusoidal stairways.

The amplification and conversion of the three-phase signal generated in the three-phase current shaping circuit 2 to a three-phase current independent of the nature and magnitude of the loads is carried out in the three-phase current amplifier 2 ·

If any output current of the three-phase current amplifier 4 rises above the allowable limit, the corresponding state of the overload circuit 10 will cause a change in the state of the signal at its output 1 007 which blocks the operation of the three-phase current amplifier 4 and also blocks the operation of the three-phase amplifier 9. Tension.

The two-state signal generated in the multivibrator 2 is also transmitted via the first galvanic isolation circuit 2 to the input 801 of the three-phase voltage forming circuit 2 at which the start of generating sinusoidal staircases, from which three alternating signals offset 120 ° relative to each other synchronized by a pulse from the output 602 of the phase shift circuit 2, which is transmitted over the second circuit of the galvanic isolation T. The phase shift circuit 2 selects a pulse to provide the desired phase shift between the three-phase current and the three-phase voltage, according to the settings, from the waveforms at the control output 305 of the three-phase current shaping circuit 2.

The amplification of the three AC signals from the three-phase voltage forming circuit 2 takes place in the three-phase voltage amplifier 2. If any output current of the three-phase voltage amplifier 2 increases above the allowable limit, the state of its overload output 1 007 changes over the corresponding voltage input of the overload circuit 10, which blocks the operation of the three-phase current amplifier 4 and also blocks the operation of the three-phase voltage amplifier 2. ·

The galvanic separation of the three-phase voltage shaping circuit 2 ^{and the} three-phase voltage amplifier 2 is due to the need to generate a three-phase voltage with a common zero in the absence of complementary transistors for the desired output voltage magnitude. Connection of amplifier with high output voltage, which is the basis of three-phase voltage amplifier is protected by MS. by the author's certificate No. 195 531.

The advantage of wiring the control transducer to the measuring transducer is that the signal passing through the galvanic isolation circuits is two-state and the galvanic isolation circuits can be easily implemented so that the transmission time does not have a significant effect on the phase shift amount and is independent of the output signal values.

The present invention finds use in the implementation of an instrument for calibrating AC measuring transducers, frequency relays, AC and phase sensitive measuring instruments. ,

Claims (1)

SUBJECT OF THE INVENTION Connection of control station for calibration of measuring transducers ensuring generation of three-phase current and three-phase voltage with digital adjustment of phase shift independent of load, setting of frequency and magnitude of output quantities and overload protection of outputs, characterized in that output an input (201) of a frequency meter (2) connected to an input (301) of a three-phase current shaping circuit (3) whose first output (302) is connected to a first input (401) of a three-phase current amplifier (4), (303) of the three-phase current shaping circuit (3) is connected to the second input (402) of the three-phase current amplifier (4), the third output (304) of the three-phase current shaping circuit (3) being connected to the third input (403) of the three-phase current amplifier. 4), whose first active output (404) is connected to one end of gal the free end load (12) of the X-weight current circuit, the other end of which is connected to a first comparative output (405) of a three-phase current amplifier (4) which is connected to the first current input (1 001) of the overload circuit (10); the output (406) of the three-phase current amplifier (4) is connected to one end of the galvanically free load (13) of the Y-phase current circuit, the other end of which is connected to the second comparative output (407) of the three-phase current amplifier (4) the current input (1 002) of the overload circuit (10), the third active output (408) of the three-phase current amplifier (4) being connected to one end of the galvanically free load (14) of the phase Z current circuit; (409) a three-phase current amplifier (4) which is connected to a third current input (1 003) of the overload circuit (10), e.g. wherein the output (101) of the multivibrator (1) is also connected to an input (501) of a first galvanic isolation circuit (5) whose output (502) is connected to an input (801) of a three-phase voltage forming circuit (8) ) is connected to a first input (901) of a three-phase voltage amplifier (9), the second output (803) of a three-phase voltage forming circuit (8) being connected to a second input (902) of a three-phase voltage amplifier (9), a three-phase voltage shaping circuit (8) is connected to a third input (903) of a three-phase voltage amplifier (9) whose first output (905) is connected to a common output (910) of a three-phase amplifier via a load (15) (9) a voltage whose second output (907) is also connected to a common output (910) of a three-phase amplifier via a common phase zero (Y) load (16) (9) a voltage whose third output (909) via a load (17) with a common z-phase voltage circuit is also connected to a common output (910) of a three-phase voltage amplifier (9), whose first overcurrent output (904) is connected to a first voltage input (1,004) of the overload circuit (10), wherein a second overcurrent output (906) of the three-phase voltage amplifier (9) is connected to a second voltage input (1,005) of the overload circuit (10), the voltage amplifier (9) is connected to a third voltage input (1 006) of the circuit (10). an overload whose output (1,007) is connected to a blocking input (4,010) of a three-phase current amplifier (4) which is connected to an input (1,101) of a third galvanic isolation circuit (11) whose output (1,102) is connected to a blocking input (9 011) of a three-phase voltage amplifier (9), the control output (305) of the three-phase current shaping circuit (3) being connected to the input (601) of the phase shift circuit (6) whose output (602) is connected to the input (602) 701) of a second galvanic isolation circuit (7), the output of which (702) is connected to a control input (805) of a three-phase voltage forming circuit (8).